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Applied Neuroscience Columbia Science Honors Program Fall 2016 Sensory Systems and Neural Circuits, Part Two Last week’s class Sensory systems and neural circuits 1. 2. 3. 4. Introduction to sensory systems Visual system Auditory system Introduction to neural circuits How do we take cues from our environment and make sense of the world around us? Sensory systems How do sensory systems work? Neurons in sensory regions of the brain respond to stimuli by firing action potentials after receiving a stimulus. Each sensory system follows a specific plan: 1. Reception 2. Transduction 3. Coding Today’s class Objective: Sensory Systems and Neural Circuits, Part Two Agenda: Sensory Systems Gustatory system (taste) Olfactory system (odor) Demo 1: Jellybean test Somatosensory system (touch and pain) Demo 2: Flavor tripping with ‘Miracle Berries’ Sensory systems What are different types of senses? Vision Hearing Smell (olfaction) Touch Pain Humans Temperature Vestibular Senses Proprioception Taste (gustation) Autonomic Senses Chemical senses Sensory systems associated with the nose and mouth (olfaction and taste) detect chemicals in the environment. Gustatory system: detects ingested, primarily water-soluble, molecules called tastants Olfactory system: detects airborne molecules called odors These systems rely on receptors in the nasal cavity, mouth or face that interact with the relevant molecules and generate action potentials. Gustatory System Objective: Understand how the gustatory system works Agenda: 1. Morphology of cells 2. Gustatory pathway v Flavor tripping with ‘Miracle Berries’ (later in the class) Gustatory System Morphology of taste buds and cell types: • Taste buds are located on papillae and are distributed across the tongue • They are also found on the oral mucosa of the palate and epiglottis • Taste buds contain 80 cells arranged around a central taste pore. Gustatory System Taste receptor cells: • Spindle shaped cells that extend from the base to the apex of taste buds • Taste solutes are transported to the taste pore and diffuse through the fluid layer to make contact with membrane receptor proteins on the microvilli and apical membrane • Taste sensitivity is dependent on the concentration of taste molecules and their solubility in saliva Gustatory System Sensory transduction: • Taste sensation can be caused by diverse tastants • Action potentials in the taste receptor cells leads to an increase in Ca2+ influx through voltage-gated channels with a release of Ca2+ from intracellular stores • In response to Ca2+, neurotransmitter is released, which causes synaptic potentials in the dendrites of the sensory nerves and action potentials in the afferent nerve fibers Gustatory System Taste distribution: • Most of the tongue is receptive to all basic tastes • There are certain regions that are most sensitive to a given taste • Bitter: across back of tongue • Sour: on side closest to the back • Salty: on side more rostral than sour • Sweet: across front of tongue Gustatory System How is salt processed? • Na+ flows down a concentration gradient into the taste receptor cell (most salts are Na+ salts, like table salt) • Na+ increases within the cell, which depolarizes the membrane and opens a voltage dependent Ca2+ channel • Ca2+ increase causes the release of neurotransmitters Gustatory System How are acids (sour tastants) processed? • Foods that are sour have high acidity (low pH) • When acids are dissolved in water, they generate H+ ions • H+ ions pass through the same channel that Na+ does • H+ blocks a K+ channel as well • The net movement of cations into the cell depolarizes the taste cell • This opens a Ca2+ channel • It causes neurotransmitter release Gustatory System How is sweet processed? • Molecules that are sweet bind to specific receptor sites and activate a cascade of 2nd messengers in certain taste cells • These molecules also bind to receptors • G-protein activates an effector enzyme-adenylate cyclase and produces cAMP • cAMP causes a K+ channel to be blocked • The cell depolarizes • Ca2+ channel opens and Ca2+ enters the cell • Neurotransmitter is released Gustatory System How is bitter processed? • Noxious chemicals in the environment are often bitter • Senses have evolved to protect and preserve • The ability to detect bitter has two separate mechanisms System 1: • Bitter tastants can directly block a K+ channel • Cell depolarizes • Ca2+ channel opens and Ca2+ floods in • Neurotransmitter is released System 2: • Bitter tastants bind to bitter receptor • G-protein activates an effector enzyme • Ca2+ is released from extracellular storage • Ca2+ increase causes neurotransmitter release Gustatory System How is umami processed? • Very similar to sweet, but slightly different downstream mechanism Gustatory System Taste neural circuitry • There is no single fiber that conducts one taste quality (i.e. sweet, bitter), but some may respond best to one quality and less well to others • Branches of nerve fibers innervate several cells within and in between different taste buds Gustatory System Propagation to the primary gustatory center Olfactory System Objective: Understand how the olfactory system works and its relation to other sensory systems Agenda: 1. Morphology of cells 2. Neural pathway v Jellybean test Olfactory System What is the olfactory system? • Discriminative and sensitive chemosensory system • Humans can detect between 1000-4000 odors • All odors can be discriminated into six major groups: floral, fruit, spicy, resin, burnt and putrid • Perception of odor begins with inhalation and transport of volatile odorants to the olfactory mucosa (located in the dorsal posterior region of the nasal cavity) Olfactory System Morphology of olfactory mucosa and cells: • The olfactory mucosa consists of a layer of columnar epithelium • There are three major cells types: olfactory sensory neurons, supporting cells and basal stem cells Olfactory System Olfactory sensory neurons: • Olfactory sensory neurons have a single dendrite that projects down to the mucus • The terminal ending of dendrites have 5-25 cilia that are embedded in the mucus • Each cilia has as many has 40 specific receptor membrane proteins for interaction with different odorant molecules • The density of these receptors is very large in humans but much bigger in lower animals Olfactory System How do odorant molecules interact with sensory receptors? • Different for hydrophilic vs hydrophobic odors: • Hydrophilic (water loving): diffuse across mucus • Hydrophobic (water fearing): bound to specific odorant binding protein and transported to each cilium for interaction with specific receptors Olfactory System Transduction of olfactory stimuli • Odorant molecules bind to the receptor which is coupled with G-proteins • The activation of adenylyl cyclase leads to the formation of cAMP with the activation of Ca2+/Na+ cation channels • The influx of these ions leads to depolarization • The generated current is graded in response to the flow rate of the odorant molecules and their concentration Olfactory System Odorants are recognized by a unique combination of receptors Olfactory System Human odor thresholds Olfactory System Neural pathway into the olfactory cortex • Olfactory sensory neurons are located in the olfactory epithelium • These neurons project axons into the olfactory bulb of the brain • These projections innervate specialized regions of the olfactory bulb called glomeruli • The terminations within the glomeruli are called mitral and tufted cells • These relay neurons project to the olfactory cortex in the brain Olfactory System Higher order olfactory processing Jellybean test demo Jellybean test Instructions 1. Partner up with a person sitting near you 2. Ask your partner to closer his/her eyes 3. Give your partner a jelly bean and ask them to chew it and guess its flavor 4. Repeat this two more times 5. Now tell your partner to close their eyes and pinch their nose 6. Give your partner a jelly bean and ask them to guess the flavor without letting go of their nose 7. Repeat this two more times 8. Switch roles What’s going on? Jellybean test What is going on? 1. Approximately 80-90% of what we perceive as taste is due to our sense of smell 2. You probably were not able to tell the specific flavor of the candy beyond a general sensation of sweetness 3. As you chew, you may have been able to identify the specific taste This is because some scent molecules volatilize and travel up to your olfactory receptors (through a passage at the back of your throat connected to your nose) Somatosensory system Objective: Understand different somatosensory senses (touch and pain) and their pathways Agenda: 1. Morphology of receptors and cells 2. Neural pathway Somatosensory System What is the somatosensory system? • Processes information about several modalities of somatic sensation The Sensory Modalities Represented by the Somatosensory Systems Modality Sub Modality Sub-Sub Modality sharp cutting pain Pain dull burning pain deep aching pain Temperature warm/hot cool/cold itch/tickle & crude touch Touch discriminative touch position (static forces) Proprioception movement (dynamic forces) touch pressure flutter vibration muscle length muscle tension joint pressure muscle length muscle tension joint pressure joint angle Somatosensory System Touch and pain • Touch and pain are part of the somatosensory system • Gives our brain information about our own body and the world around us • Interoception: sensing information about our own body • Exteroception: sensing information about the world around us Somatosensory receptors are located all over the body, from the surface of our skin to deep in our joints. Somatosensory System Different modalities Cutaneous senses: senses of the skin Proprioception: body position Kinesthesis: body movement Nociception: pain and discomfort There might be a fifth modality: pleasant touch Somatosensory System Different receptor types are sensitive to specific stimuli (cutaneous senses) • Different types of somatosensory information activate different receptors • Activation of receptors lead to electrical nerve pulses (transduction) • Three main groups of receptors in skin: mechanoreceptors, thermoreceptors, chemoreceptors • Mechanoreceptors: respond to mechanical stimuli (like stretching or vibration of skin) • Thermoreceptors: respond to hot or cold temperatures • Chemoreceptors: respond to certain types of chemicals either applied externally or released within the skin (i.e histamine from an inflammation) Somatosensory System Categories of low-threshold mechanoreceptors Somatosensory System Different receptor types are sensitive to specific stimuli (nociception) • Different types of somatosensory information activate different receptors • Experience of pain usually starts with the activation of nociceptors • These receptors fire specifically to tissue-damaging stimuli • Most nociceptors are either chemoreceptors or mechanoreceptors • Chemoreceptors: when tissue is damaged or inflamed, certain chemicals are released from cells and activate these receptors • Mechanoreceptors: respond to intense mechanical stimulation Somatosensory System Action potentials in receptor cells travel at different speeds Using stepping on a pin as an example • When you step on a pin, you activate many mechanoreceptors (many of which are nociceptors) • Sensation changes over time: probably feel a sharp stab at first and then a wave of aching pain • Sharp pain: signaled via fast-conducting A-fibers, which project to the somatosensory cortex • Aching pain: a separate, simultaneous signal sent from the nociceptors in feet via C-pain fibers to the insular cortex and other brain regions involved in emotion Stepping on a pin is made up of two separate signals: discriminatory (used to localize touch) and affective (tells us that stepping on a pin is bad) Somatosensory System Somatosensory cortex organization • The somatosensory cortex is somatotopically organized • The sensory signals are represented according from where in the body they come from • Homonculus: model of bodies distorted to reflect the relative space that body parts occupy in the somatosensory cortex Somatosensory System Case study: rodent barrel cortex Integrating systems Understanding spiciness Integrating systems Understanding spiciness TRPV1 Receptor: thermoreceptor noxious heat detector Integrating systems There are other types of thermoreceptors as well Temperature sensation (C) ‘Miracle Berry’ demo ‘Miracle Berry’ demo What are miracle berries? • Synsepalum dulcificum • Plant native to West Africa • Contains a glycoprotein called miraculin, which binds to the tongue’s taste buds when the fruit is consumed • It acts as a sweetness inducer when it comes in contact with acids • Causes bitter and sour foods to taste sweet ‘Miracle Berry’ demo Instructions 1. Place one mberry tablet on your tongue and dissolve completely (takes about 10 minutes) 2. Taste the following items: grapefruit juice, lime juice, lemon juice, orange juice and sriracha 3. Record how the different items taste How do you think Miracle Berries work? ‘Miracle Berry’ demo How do these berries work? 1. Mechanism understood by team of researchers at the University of Tokyo (led by Keiko Abe) 2. Used a system of cultured cells that let them test taste receptors at various levels of acidity and alkalinity 3. Found that miraculin bound strongly to sweet taste buds, but unlike sugar or aspartame, doesn’t activate them at a neutral pH 4. When acid is introduced, the protein changes shape and turns on the taste bud This causes the ultra-sweet sensation that drowns out the sour taste. ‘Miracle Berry’ demo How do these berries work? • • When sour food is swallowed, miraculin returns to its old inactive shape and remains bound to the sweet receptor for an hour or so Miraculin also disrupts detection of sweet foods. If you have sugar after consuming a miracle berry, you cannot taste it. However, after introducing a little acid, the sugar tastes sweeter than ever.